Platform for authoring, storing, and searching workflows

ABSTRACT

An authoring platform for authoring a client workflow includes an arrangement of shapes representing steps and connections representing relationships between the steps. Online content retrieved from an online resource may be associated with steps of the client workflow. An authoring service receives the client workflow from the client interface via a network and directs a graph database to store a database workflow corresponding to the client workflow. A search platform is provided for creating and searching workflows using a tag database taxonomy. An author creates a workflow wherein a tag is linked to a workflow item. The workflow is stored as a database workflow and a node in the database workflow representing the workflow item is linked to a node in the database taxonomy representing the tag. Multiple workflows are created in a similar manner to link the workflows to the database taxonomy to provide efficient searching of the workflows.

CROSS-REFERENCE TO RELATED APPLICATIONS Field of the Invention

This application is a continuation of the co-pending U.S. patentapplication titled, “PLATFORM FOR AUTHORING, STORING, AND SEARCHINGWORKFLOWS,” filed on Jun. 3, 2016 and having Ser. No. 15/173,557, whichclaims the benefit of the U.S. provisional patent application Ser. No.62/195,235, filed on Jul. 21, 2015. The subject matter of these relatedapplications is hereby incorporated herein by reference.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention generally relates to computer science and, morespecifically, to a platform for authoring, storing, and searchingworkflows.

Description of the Related Art

The complexity of some software applications makes the learning curvewith respect to those software applications very steep. In order toimprove efficiency and software product familiarity, past efforts havebeen made to create user workflows that provide guidance andinstructions to users for solving the specific problems being worked onby users with the software or for achieving certain goals or outcomewith the software. A workflow may describe, for example, a sequence ofsteps and functions a user can execute to solve a particular problem orachieve a particular goal. In some cases, a workflow may be representedgraphically, with geometric shapes representing the different steps andfunctions of the workflow that need to be taken by the user. Thus,workflows are very effective tools for providing users with quick visualunderstandings of the overall steps that need to be taken to solvecertain problems or to achieve certain goals.

One drawback of conventional workflows, however, is that the workflowstypically include only a limited amount of description and content forthe different steps depicted within the workflow. For example, aworkflow may include only a title for a particular step and/or a brieftextual description of the step. A further drawback is that conventionalworkflows are not captured and retained in a way that allows largenumbers of workflows to be easily stored and retrieved. An additionaldrawback is that conventional workflows are not organized or related inways that allow easy searching of relevant workflows to allow workflowsto be easily shared among users. Because of the problems surroundingstoring and retrieving workflows and relating workflows to one another,many workflows generated by past users are not shared with currentusers, which results in substantial inefficiencies by forcing currentusers to “recreate the wheel” when using complex software applications.

As the foregoing illustrates, there is a need in the art for moreeffective ways to author, store, and search workflows.

SUMMARY OF THE INVENTION

Various embodiments include a computer-implemented method for authoringa workflow. The method includes receiving, at a server computer, aclient workflow comprising an arrangement of shapes and connections.Each shape represents a step of the client workflow and each connectionrepresents a relationship between two steps of the client workflow. Themethod also includes generating, at the server computer, a set ofdatabase queries for producing a database workflow corresponding to theclient workflow. The database workflow comprises an arrangement of stepnodes and step edges, each step node representing a step of the clientworkflow and each step edge representing a relationship between twosteps of the client workflow. The method further includes sending theset of database queries to a graph database for execution.

At least one advantage of the disclosed technique is that it enablesauthoring of workflows that may include a wide range of content,including online content. Another advantage of the disclosed techniqueis that it enables efficient storing and searching of a large number ofworkflows using a graph database.

Various embodiments include a computer-implemented method for searchingworkflows. The method includes receiving, at a server computer, a searchtag. The method also includes producing, at the server computer, a setof database queries for performing a search within a graph databasebased on the search tag. The graph database stores a plurality ofworkflows and a tag taxonomy, each workflow including a plurality ofworkflow item nodes and the tag taxonomy including a plurality of tagnodes representing a plurality of tags. The method further includessending the set of database queries to the graph database for execution.

At least one advantage of the disclosed technique is that fast andefficient searches of a large number of workflows linked to a taxonomyof tags may be performed.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above recited features of the inventioncan be understood in detail, a more particular description of theinvention, briefly summarized above, may be had by reference toembodiments, some of which are illustrated in the appended drawings. Itis to be noted, however, that the appended drawings illustrate onlytypical embodiments of this invention and are therefore not to beconsidered limiting of its scope, for the invention may admit to otherequally effective embodiments.

FIG. 1 illustrates an authoring platform environment configured toimplement one or more aspects of the present invention;

FIG. 2 illustrates a screenshot of a client interface for authoring aclient workflow, according to various embodiments;

FIG. 3 illustrates a screenshot of a client interface for associatingonline content with a client workflow, according to various embodiments;

FIG. 4 illustrates a conceptual diagram of a graph database workflowstored in the graph database of FIG. 1 , according to variousembodiments;

FIG. 5 illustrates a flow diagram of method steps for authoring aworkflow, according to various embodiments;

FIG. 6 illustrates a flow diagram of method steps for retrieving andpresenting a workflow, according to various embodiments;

FIG. 7 illustrates a screenshot of a client interface for displayingcontent associated with a client workflow, according to variousembodiments;

FIG. 8 illustrates an authoring and search platform environment,according to various embodiments;

FIG. 9 illustrates a conceptual diagram of a database taxonomy stored inthe graph database of FIG. 8 , according to various embodiments;

FIG. 10 illustrates a screenshot of a client interface for linking a tagwith a workflow item, according to various embodiments;

FIG. 11 illustrates a conceptual diagram of two database workflowslinked to a database taxonomy, according to various embodiments;

FIG. 12 illustrates a flow diagram of method steps for authoring andstoring workflows based on a taxonomy, according to various embodiments;

FIG. 13 illustrates a flow diagram of method steps for searching andpresenting workflows based on a taxonomy, according to variousembodiments;

FIG. 14 illustrates a conceptual diagram of a search process based onthe database taxonomy of FIG. 11 , according to various embodiments;

FIG. 15 illustrates an example server computer of FIGS. 1 and 8 ,according to various embodiments; and

FIG. 16 illustrates an example client computer of FIGS. 1 and 8 ,according to various embodiments.

DETAILED DESCRIPTION

In the following description, numerous specific details are set forth toprovide a more thorough understanding of the present invention. However,it will be apparent to one of skill in the art that the presentinvention may be practiced without one or more of these specificdetails. In other instances, well-known features have not been describedin order to avoid obscuring the present invention.

The following description is divided into two sections. Section Idescribes a platform for authoring and storing workflows using a graphdatabase. Section II describes a platform for searching workflows usinga graph database.

Section I: Platform for Authoring and Storing Workflows

Users of a given software product may wish to create workflows thataugments the documentation created by the provider of the softwareapplication. Such users are generally referred to as authors. A workflowmay provide valuable insight for both novice and experienced users forsolving particular problems or achieving particular goals related to thesoftware application. For example, a workflow may be created toillustrate a process for editing images in a photo editor application.In other embodiments, a workflow may be produced for any type ofprocess, whether related to a software application or not. For example,a workflow may be created to illustrate a process for changing oil in anautomobile, setting up a home theater system, writing a thesis paper,etc. As used herein, a workflow comprises a sequence or series ofconnected steps for performing a particular process (which solves aparticular problem or achieves a particular goal). A step of a workflowmay comprise any operation, function, task, or the like. A process of aworkflow may comprise any method, procedure, algorithm, or the like. Aworkflow may comprise a graphical/visual diagram that represents theprocess. A workflow diagram comprises an arrangement of geometric shapesand connections, the geometric shapes representing steps of the workflowand the connections representing relationships between the steps. Ingeneral, a workflow may comprise any process that can be represented bya graphical flow diagram.

Typically a workflow includes only a limited amount of description foreach step of the workflow, such as a title and a brief text descriptionof the step. Embodiments described herein provide an authoring platformfor creating workflows that may include a wide range of content,including digital online content. In these embodiments, online contentmay be associated with one or more steps of the workflow. Workflowscreated using the authoring platform may be efficiently stored to agraph database. A workflow may be created by an author via a web-baseduser interface executing on a client computer that connects to a servercomputer which manages the graph database. The server computer may actas an interface between the client computer and the graph database byreceiving the workflow (and associated content) from the client computerand managing and directing the storage of the workflow to the graphdatabase. Each workflow may be stored to the graph database as a graphstructure comprising an arrangement of nodes and edges, the nodesrepresenting steps of the workflow and the edges representingrelationships between the steps. A workflow that is created by theauthoring platform may be later retrieved from the graph database anddisplayed at the client computer. Thus, the authoring platform maycomprise a web-based platform for creating and retrieving workflowsincluding a wide range of content that is connected in the back-end to agraph database.

Authoring and Storing Environment

FIG. 1 illustrates an authoring platform environment 100 configured toimplement one or more aspects of the present invention. The authoringplatform environment 100 enables authoring and storing of workflows to agraph database. As shown, the environment 100 includes at least oneclient computer 130 (e.g., 130A-130N), a server computer 110, and atleast one content server 140 (e.g., 140A-140N) coupled via a network120. Each of client computer 130, server computer 110, and contentserver 140 may comprise computer hardware components such as memory forstoring software application(s) and data and processors that execute thesoftware application(s) to provide processing engines that enable theinventive operations and functions described herein. The computerhardware components of the server computer 110 and client computer 130are discussed below in relation to FIGS. 15-16 . In this regard, eachclient computer 130 hosts and executes a client interface engine 132,the server computer 110 hosts and executes an authoring service engine112 and a presentation service engine 114. The server computer 110 isalso coupled to a graph database 116 comprising a database engine 117that organizes and stores database workflows 118.

As shown in FIG. 1 , the client computer 130, server computer 110, andthe graph database 116 each stores (e.g., in memory or storage) aseparate and distinct version/representation of a workflow. For example,each client computer 130 stores a client workflow 134 that is created byan author, the server computer 110 stores a corresponding serverworkflow 115 that is an internal server representation of the clientworkflow 134, and the graph database 116 stores a corresponding databaseworkflow 118 that is a graph database representation of the clientworkflow 134. In some embodiments, a client workflow 134 may comprise adisplayed artifact (displayed in the client interface 132 at the clientcomputer 130) having underlying data records in the Scalable VectorGraphics (SVG) XML image format and comprise a Javascript object in amemory of the client computer 130. In some embodiments, a serverworkflow 115 may comprise an internal abstract representation/model ofthe client workflow 134 that exists in a memory of the server computer110 in the form of a Javascript object. A database workflow 118 maycomprise a compact persistent/permanent record of the client workflow134 in the form of nodes, relationships, and property records (as wellas database artifacts such as indexes and constraints). The databaseworkflow 118 may also exist in an expanded form in a memory of theserver computer 110 when the database engine 117 is activated, wherebythe form of the database workflow 118 is configured to provide anoptimal performance database environment after the expansion. Ingeneral, the database workflow 118 may comprise a persistent/permanentrecord of a workflow, whereas a server workflow 115 may comprise atemporary “working copy” of a workflow which is revealed by databasequeries.

Each different version of the workflow may comprise a different dataformat and syntax that is appropriate for the computing device on whichthe workflow version is stored. In general, the client workflow 134 isunderstandable and executable by the client interface 132 residing onthe client computer 130 and is not understandable and executable by thedatabase engine 117 residing on the database 116. Similarly, thedatabase workflow 118 is understandable and executable by the databaseengine 117 residing on the database 116 and is not understandable andexecutable by the client interface 132 residing on the client computer130. The authoring service 112 residing on the server computer 110 mayproduce a server workflow 115 to assist translations between a clientworkflow 134 on the client computer 130 and a corresponding databaseworkflow 118 on the database 116. As used herein, a “workflow item”comprises a workflow or any element or component of a workflow,including the overall workflow, a step, a shape or node representing astep, a relationship between steps, a connection or edge representing arelationship, associated content, and a node representing associatedcontent.

An author/user may interact with a client interface 132 executing on theclient computer 130 to create and/or modify a client workflow 134. Theclient interface 132 may comprise a combined web-browser and workfloweditor application. The client interface 132 may include any workfloweditor that is capable of creating and/or modifying a graphical diagramthat represents a workflow via an arrangement of connected geometricshapes (discussed in relation to FIG. 2 ). The web-browser applicationof the client interface 132 includes a software plug-in that allows theweb-browser to interact with the service engines of the server computer110 (such as authoring service engine 112 and a presentation serviceengine 114). The author/user may interact with the client interface 132to create geometric shapes representing steps of the workflow andconnections between the geometric shapes representing the relationshipsbetween the steps to produce the client workflow 134. Each shape/stepmay have associated metadata, such as a title and/or brief descriptionof the shape/step. In some embodiments, the author/user may alsoassociate a wide range of online content (such as content 142 from acontent server 140) with the client workflow 134 or any step of theclient workflow 134 (discussed in relation to FIG. 3 ). In theseembodiments, a client workflow 134 may comprise a graphical diagram thatrepresents a workflow as well as any associated content. The clientinterface 132 then sends client payloads representing the userinteractions with the client workflow 134 to the authoring service 112residing on the server computer 110. Each client payload may comprise aset of client requests and client metadata representing the userinteractions with the client workflow 134.

The authoring service 112 comprises application logic or server API thatresides and executes on the server computer 110. The authoring service112 receives a client payload representing the user interactions for aclient workflow 134 to produce an internal abstract representation/modelof the client workflow 134 (referred to herein as a server workflow115). In general, the authoring service 112 may produce the serverworkflow 115 to assist translations between the client workflow 134 onthe client computer 130 and a corresponding database workflow 118 on thedatabase 116. Based on the received client payload and the internalserver workflow 115, the authoring service 112 produces a set ofdatabase query statements that cause and direct the database engine 117of the database 116 to store the client workflow 134 as a graphstructure (referred to herein as a database workflow 118).

In some embodiments, the database 116 comprises a graph database thatstores a client workflow 134 as a graph structure comprising anarrangement of nodes and edges. A node of the graph structure mayrepresent the workflow, a particular step of the workflow, or associatedcontent. Each node may have associated metadata, such as a title and/orbrief description of the node. An edge comprises a connection betweentwo nodes and represents a specific relationship between the two nodes.When receiving a set of database queries from the authoring service 112,the database engine 117 executes the database queries to store theclient workflow 134 as a graph structure (database workflow 118). Thedatabase engine 117 may store each client workflow 134 as a separatedatabase workflow 118 in the database 116.

An author/user may initially interact with the client interface 132 tocreate a new client workflow 134 and input text descriptors (e.g., atitle and/or a brief description) for the new client workflow 134. Theclient interface 132 sends a client payload representing the userinteractions to the authoring service 112 which creates a new serverworkflow 115 for the client workflow 134 and generates a set of databasequeries to direct the database engine 117 to create a new databaseworkflow 118 (comprising a node representing the new database workflow118 and associated metadata for the text descriptors). The databaseengine 117 executes the query statements and produces and stores a newdatabase workflow 118 to the database 116.

After creating the new client workflow 134, the user may continue tointeract with the client interface 132 to modify the client workflow134. For example, the user may add, remove, or edit the steps,relationships between the steps, or associated content of the clientworkflow 134. After receiving each user interaction/modification of theclient workflow 134, the client interface 132 sends a client payloadrepresenting the user interaction/modification to the authoring service112 which modifies the server workflow 115 to reflect the modificationsto the client workflow 134 according to the received client payload. Inaddition, based on the received client payload and the modifications tothe server workflow 115, the authoring service 112 generates a set ofdatabase query statements that directs the database engine 117 to modifythe database workflow 118 to likewise reflect the modifications to theclient workflow 134. The database engine 117 receives and executes thequery statements to modify the database workflow 118 accordingly.

In some embodiments, user interactions/modification to the clientworkflow 134 automatically causes corresponding/equivalent modificationsto the corresponding database workflow 118 in real-time. In particular,each user interaction with the client workflow 134 automatically causesthe client interface 132 to send a client payload (representing the userinteraction) to the authoring service 112 in real-time. Upon receivingthe client payload, the authoring service 112 automatically modifies thecorresponding server workflow 115 and produces database queries tomodify the corresponding database workflow 118 in real-time. Thus, eachuser interaction/modification to the client workflow 134 automaticallycauses corresponding/equivalent modifications to database workflow 118that is stored persistently in the database 116, without requiring theuser to request saving/storing the modified client workflow 134 to thedatabase 116.

As described above, the authoring service 112 translates the receivedclient payload from the client interface 132 to a set of database querystatements that is understandable and executable by the database engine117. The client payload from the client interface 132 may comprise a setof client requests that are understandable and executable by a workfloweditor application of the client interface 132 for creating or modifyinga client workflow 134. The client requests from the client interface 132are typically not executable by a database engine 117 of a graphdatabase 116. Thus, the authoring service 112 may act as an intermediaryto translate the client requests from the client interface 132 to a setof database query statements that is understandable and executable bythe database engine 117.

As described above, each client workflow 134 may be stored to the graphdatabase 116 as a graph database workflow 118 with nodes (representingsteps) and edges (representing relationships between the steps). Giventhe inherent structural similarity of a client workflow diagram 134(comprising geometric shapes representing steps and connectionsrepresenting relationships between the steps) and a graph databaseworkflow 118 (comprising nodes representing steps and edges representingrelationships between the steps), a graph database 118 enables efficientstorage, organization, and retrieval of client workflows 132.Furthermore, a graph database 116 enables efficient relationship linkingbetween workflows and quick searching of a large number of workflows(discussed below in Section II).

A client workflow 132 that is created by the authoring platform 100 andstored to the database 116 as a corresponding database workflow 118 maybe later retrieved from the database 116 and displayed at a clientinterface 132. A database workflow 118 stored to the database 116 may beaccessed by any client computer 130 executing a client interface 132 viathe network 120 (assuming the user has access permissions). Thus, theauthoring platform 100 enables web-based access to database workflows118 that allows broad collaboration and distribution of the databaseworkflows 118 to any users (having access permission) across the web.

In general, when retrieving a database workflow 118 for display, theclient interface 132 connects and communicates with (via the network120) a presentation service engine 114 residing on the server computer110. A user may submit a request for a particular database workflow 118through the client interface 132 which sends the request to thepresentation service 114. In response, the presentation service 114sends a database query statement to the database engine 117 for therequested database workflow 118. In response, the database engine 117sends a graph representation of the requested database workflow 118. Forexample, the graph representation may comprise a JavaScript ObjectNotation (JSON) representation comprising a list of nodes and edgescomprising the requested database workflow 118. The presentation service114 then translates the graph representation of the requested databaseworkflow 118 to a client representation of the requested databaseworkflow 118 that is understandable by the client interface 132. Theclient interface 132 then receives and displays the clientrepresentation of the database workflow 118 as a client workflow 134.

Authoring and Storing Workflows to a Graph Database

FIG. 2 illustrates a screenshot of a client interface 132 for authoringa client workflow 134, according to various embodiments. The clientinterface 132 may comprise a workflow editor application capable ofcreating and/or modifying a client workflow 134. The client workflow 134may comprise any graphical diagram that represents a workflow.

As used herein, a workflow comprises a sequence or series of connectedsteps for performing a particular process. A step of a workflow maycomprise an operation, function, task, or the like. A process maycomprise a method, procedure, algorithm, or the like. A workflow maycomprise a graphical/visual diagram that represents the process as anarrangement of connected geometric shapes 210. Each geometric shape 210in the diagram may represent a step of the workflow. A workflow maycomprise different types of steps, such as a terminal step (e.g., startor end), process step (where something is performed), or decision step(e.g., where a decision is made resulting in a Yes/No or True/Falsedecision). Each different type of step may be represented by a differenttype of geometric shape 210. For example, a terminal step may berepresented by an oval or rounded rectangle, a process step may berepresented by a rectangle, a decision step may be represented by arhombus.

Each connection 220 in the workflow diagram connects two geometricshapes 210 (representing two steps of the workflow) and indicates thesequential relationship between the two steps within workflow. Thus, theconnections 220 between geometric shapes 210 may indicate thesequence/ordering of steps of the workflow (such as a first step thatprecedes a second step and a third step that follows the second step).Each connection 220 may be graphically/visually represented by an arrowindicating the sequence/ordering of the two connected shapes/steps 210.

An author/user may interact with the client interface 132 (executing onthe client computer 130) to create and/or modify a client workflow 134.For example, the user may initially interact with the client interface132 to create a new client workflow 134 and input text descriptors 230(e.g., a title and/or a brief description) for the new client workflow134. Creating a new client workflow 134 in the client interface 132automatically causes a new database workflow 118 to be produced andstored in the database 116. After creating the new client workflow 134,the user may continue to interact with the client interface 132 tomodify the client workflow 134. For example, the user may add, remove,or edit shapes 210 (representing steps), connections 220 (representingrelationships between the steps), or associated content of the clientworkflow 134. The user may also interact with the client interface 132to input text descriptors 230 (e.g., a title and/or a brief description)for a shape/step 210 of the client workflow 134. Modifying the clientworkflow 134 in the client interface 132 automatically causes thecorresponding database workflow 118 to be modified and stored in thedatabase 116 in real-time.

In some embodiments, the user may interact with the client interface 132to associate content with one or more shapes/steps 210 of the clientworkflow 134. In these embodiments, the associated content may comprisea wide range of content, such as digital online content 142 from acontent server 140 that is accessed via a network 120 (e.g., Internet).For example, the associated content may comprise multimedia content(audio or video), images, websites, Uniform Resource Locators (URLs),tutorials, articles, blogs, discussion forums, documents, presentationslides, downloadable files, etc. The associated content may originatefrom a variety of online sources, such as various content servers140A-N. A content server 140 may correspond to a physical computingsystem (e.g., a system in a data center) or may be a virtual computinginstance executing within a computing cloud. The content server 140 maypresent the content 142 within websites or webpages. Thus, the authoringplatform 100 allows an author to associate content from virtually anydigital online web resource (or other source of information).

FIG. 3 illustrates a screenshot of a client interface 132 forassociating online content with a client workflow 134, according tovarious embodiments. The client interface 132 may comprise a workfloweditor and a web-browser application capable of accessing online content142 from content servers 140 via a network 120 (e.g., Internet). Via theclient interface 132, the author/user may first select a specificshape/step 210 of the client workflow 134 to associate content with theshape/step 210. For example, the user may select (e.g., by clicking onor hovering over a cursor over) a particular shape/step 210 causing theclient interface 132 to display a URL field 310 in response. The usermay then input a URL that specifies the location of a web resource thatcomprises the associated content.

Upon receiving the URL of a web resource, the client interface 132 mayexecute or implement a web crawler or web data extractor service tocrawl the web resource located at the received URL to extract metadatafrom the web resource. Examples of web crawler services that may beimplemented by the client interface 132 include Bingbot by Microsoft®,FAST Crawler by Fast Search & Transfer®, Googlebot by Google® and thelike. For example, the extracted metadata may include an author name,title, text content (text descriptions), image content, multimediacontent (audio and video), etc. The extracted metadata may be referredto herein as content metadata. The client interface 132 then generatesand sends a client payload representing the user interaction with theclient workflow 134 to the authoring service 112. In these embodiments,the client payload may include the extracted content metadata that issent to the authoring service 112. The authoring service 112 then causesand directs the corresponding database workflow 118 stored in thedatabase 116 to associate the content with the specific node/step of thedatabase workflow 118. For example, the authoring service 112 mayassociate online content 142 (e.g., video) with a specific node/step ofthe database workflow 118 in response to the user submitting the URL ofa content server 140 (e.g., video sharing website).

FIG. 4 illustrates a conceptual diagram of a graph database workflow 118stored in the graph database 116 of FIG. 1 , according to variousembodiments. The database workflow 118 may be created for acorresponding client workflow 134 that is created by a user in theclient interface 132. The database engine 117 may store each clientworkflow 134 as a separate database workflow 118 in the database 116.

As shown, the database workflow 118 represents a workflow (such asclient workflow 134) as a graph structure comprising workflow item nodes410 and edges 420. A workflow item node 410 of the database workflow 118may represent the overall workflow, a particular shape/step of theworkflow, or associated content. A database workflow 118 may includedifferent types of nodes, each different type of node representing adifferent type of workflow item. As used herein, a workflow noderepresents the overall workflow, a step node represents a shape/step,and a content node represents associated content. In some embodiments,the database workflow 118 includes at least one content node thatrepresents online content associated with a particular shape/step of theworkflow. For a content node, the associated content may also be storedto the database 116 and linked to the content node. Also, each node 410of the database workflow 118 comprises a unique identifier (assigned bythe authoring service 112). In general, a node representing a workflowitem may be referred to as a workflow item node (which comprises aworkflow node, step node, or content node).

An edge 420 comprises a connection between two node 410 s and representsa relationship between the two node 410 s. A database workflow 118 mayinclude different types of edges 420 representing different types ofrelationships between two node 410 s, such as a contain/workflow edge,precede/step edge, or associated/content edge. A contain edge 420connects a first node 410 representing the workflow and a second node410 representing a step contained within the workflow, the contain edge420 representing this relationship between the workflow and thecontained step. A contain edge may also be referred to herein since aworkflow edge since it connects to a workflow node. A precede edge 420connects two node 410 s that represent two steps of the workflow wherebya first step precedes a second step, the precede edge 420 representingthe sequence/ordering relationship between the two steps of theworkflow. Thus, the edges 420 may indicate the sequence/ordering ofsteps of the workflow (such as a first step that precedes a second stepand a third step that follows the second step). A precede edge may alsobe referred to herein as a step edge since it connects wo step nodes. Anassociated edge 420 connects a first node 410 representing a first stepof the workflow and second node 410 representing content associated withthe first step of the workflow, the associated edge 420 representingthis associated relationship between the first step and the content. Anassociated edge may also be referred to herein as a content edge sinceit connects to a content node. As shown in FIG. 4 , an edge 420 mayinclude a description of the relationship, such as “contains” for acontain/workflow edge, “precedes” for a precede/step edge, or“associated” for an associated/content edge.

FIG. 5 illustrates a flow diagram of method steps for authoring aworkflow, according to various embodiments. Although the method stepsare described in conjunction with the systems of FIGS. 1-4 , personsskilled in the art will understand that any system configured to performthe method steps, in any order, is within the scope of the invention. Insome embodiments, the method 500 may be performed by the clientinterface 132 executing on a client computer 130, an authoring serviceengine 112 executing on a server computer 110, and a database engine 117executing on a database 116.

The method 500 begins when the client interface 132 establishes anauthenticated connection with the authoring service 112 via a network120 (at step 505). For example, the client interface 132 may receive ausername and password from an author/user and submit the username andpassword to the authoring service 112. The authoring service 112validates the username and password to ensure that the author/user haspermission to access the authoring service 112.

The client interface 132 then receives (at step 510) a user interactioncreating a new client workflow 134 or modifying a client workflow 134.For example, the received user interaction may comprise the author/usercreating a new client workflow 134 and inputting text descriptors (e.g.,author name, title, and/or brief description) for the new clientworkflow 134. For example, the user may add, remove, or edit the steps,relationships between the steps, or associated content of the clientworkflow 134. As shown in FIG. 2 , the received user interaction maycomprise an adding, removing, or editing of one or more geometric shapes210 representing steps and/or one or more connections 220 representingrelationships between the steps. As shown in FIG. 3 , the received userinteraction may comprise an adding, removing, or editing of contentassociated with a specific shape/step of the client workflow 134. In thecase where the associated content comprises an online resource specifiedby a URL, the client interface 132 implements a web crawler service toextract content metadata from the online resource.

The client interface 132 then produces and sends (at step 515) a clientpayload to the authoring service 112, the client payload representingthe received user interaction. The client payload may comprise clientrequests and client metadata representing the received user interactionwith the client workflow 134. Thus, the client interface 132 may receivea user interaction and translate the user interaction to client requestsand client metadata. For example, the client requests may comprise HTTPRepresentational State Transfer (RESTful) web-server requests (asoftware architectural style common on the World Wide Web). The clientmetadata may comprise different types of metadata including generalmetadata, context metadata, and content metadata. Each received userinteraction affects one or more workflow items in the client workflow134, such as the overall client workflow 134 or a step, connection, orassociated content within the client workflow 134. General metadata mayidentify each affected workflow item and specify text descriptors foreach affected workflow item (such as author name, title, and/or brieftext description). Context metadata may specify the context of eachaffected workflow item within the client workflow 134, such asrelationships between the affected workflow items and unaffectedworkflow items within the client workflow 134. For example, contextmetadata may specify that a first step precedes a second step within theclient workflow 134 or that a content is associated with a second stepof the client workflow 134. Content metadata may comprise metadataextracted from an online resource comprising an associated content. Insome embodiments, the client payload is formatted in the JSON format.

The authoring service 112 receives (at step 520) the client payload fromthe client interface 132 and creates or modifies an internal serverworkflow 115 corresponding to the client workflow 134 based on thereceived client payload. In particular, the authoring service 112 maycompare the client requests and client metadata (contained in thereceived client payload) to the server workflow 115 to determine amodification/difference between the client requests and client metadataand the server workflow 115. The authoring service 112 may then modifythe server workflow 115 based on the determined modification/difference.Thus, the modifications to the server workflow 115 reflect themodifications to the client workflow 134 made by the user interaction.

Based on the received client payload and the modifications to the serverworkflow 115, the authoring service 112 also generates (at step 525) aset of database query statements that directs the database engine 117 tocreate or modify a graph database workflow 118 corresponding to theclient workflow 134 and the server workflow 115. In particular, theauthoring service 112 may translate the modifications made to the serverworkflow 115 (in step 520) to a set of database query statements thatproduce corresponding/equivalent modifications to the graph databaseworkflow 118. The set of database query statements may also specify aunique identifier for each affected node of the database workflow 118.The authoring service 112 also sends (at step 525) the set of databasequery statements to the database engine 117.

The database engine 117 receives and executes (at step 530) the set ofdatabase query statements on a graph database workflow 118 correspondingto the client workflow 134 and the server workflow 115. The set ofdatabase query statements are understandable and executable by thedatabase engine 117 for creating a new database workflow 118representing a new client workflow 134 or modifying a database workflow118 representing a client workflow 134, the new database workflow 118 ormodifications to a database workflow 118 being automatically andpersistently stored to the database 116. The modifications to thedatabase workflow 118 reflect the modifications to the server workflow115 and the client workflow 134 made by the user interaction.

The client interface 132 then determines (at step 535) whether a userinput is received for quitting the session or logging off the authoringservice 112. If so, the method 500 ends. If not, the method 500continues at step 510 where the client interface 132 receives a new userinteraction with the client workflow 134.

Overall, multiple iterations of the method 500 are performed to processmultiple user interactions that create and modify the client workflow134 to produce the completed client workflow 134. Thus, through multipleiterations of the method 500, the client interface 132 produces acompleted client workflow comprising an arrangement of shapes andconnections, each shape representing a step of the client workflow andeach connection representing a relationship between two steps of theclient workflow. The completed client workflow 134 is received at aauthoring service 112 which produces a set of database queries forproducing a database workflow 118 corresponding to the completed clientworkflow 134. The database workflow 118 comprises an arrangement of stepnodes and step edges, each step node representing a step of the clientworkflow and each step edge representing a relationship between twosteps of the client workflow. The set of database queries are sent tothe graph database 116 to produce and store the database workflow 118corresponding to the completed client workflow 134.

Associated content for a particular step of the client workflow 134 mayalso be received from the client interface 132 at the authorizingservice 112. In response, the authorizing service 112 produces a set ofdatabase queries for producing a content node and content edge in thedatabase workflow 118, the content node representing the associatedcontent and the content edge representing an associated relationshipbetween the content node and a step node representing the particularstep of the client workflow 134. The set of database queries are sent tothe graph database 116 to add the content node and content edge to thedatabase workflow 118 and store and link the associated content with thedatabase workflow 118 in the database 116.

Presenting Workflows from a Graph Database

A client workflow 132 that is created by the authoring platform 100 andstored to the database 116 as a corresponding database workflow 118 maybe later retrieved from the database 116 and displayed at a clientinterface 132. A database workflow 118 stored to the database 116 may beaccessed by any client computer 130 executing a client interface 132 viathe network 120 (assuming the user has access permissions). Thus, theauthoring platform 100 enables web-based access to database workflows118 that allows broad collaboration and distribution of the databaseworkflows 118 to any users (having access permission) across the web.

FIG. 6 illustrates a flow diagram of method steps for retrieving andpresenting a workflow, according to various embodiments. Although themethod steps are described in conjunction with the systems of FIGS. 1-4, persons skilled in the art will understand that any system configuredto perform the method steps, in any order, is within the scope of theinvention. In some embodiments, the method 600 may be performed by theclient interface 132 executing on a client computer 130, an presentationservice engine 114 executing on a server computer 110, and a databaseengine 117 executing on a database 116.

The method 600 begins when the client interface 132 establishes anauthenticated connection with the presentation service 114 via a network120 (at step 605). For example, the client interface 132 may a receive ausername and password from an author/user and submit the username andpassword to the presentation service 114. The presentation service 114validates the username and password to ensure that the author/user haspermission to access the presentation service 114.

The client interface 132 then receives (at step 610) a user inputrequesting a particular database workflow 118 (corresponding to apreviously created client workflow 134). For example, the user may inputthe author name and title of the desired database workflow 118. Theclient interface 132 also sends (at step 610) a client request for thedesired database workflow 118 to the presentation service 114. Inparticular, the client interface 132 sends a request for arepresentation of desired database workflow 118 that is understandableand executable/displayable by the client interface 132 as a clientworkflow 134.

The presentation service 114 receives (at step 620) the client requestfor the database workflow 118 and sends a database query statement tothe database engine 117 for the database workflow 118. The databaseengine 117 receives (at step 625) the database query statement for thedatabase workflow 118 and sends a graph representation of the requesteddatabase workflow 118 to the presentation service 114. For example, thegraph representation may comprise a JSON representation comprising alist of nodes and edges comprising the requested database workflow 118.In some embodiments, the graph representation does not include anyassociated content.

The presentation service 114 then receives and translates (at step 630)the graph representation of the database workflow 118 to a clientrepresentation of the database workflow 118 that is understandable andexecutable/displayable by the client interface 132. For example, thepresentation service 114 may “flatten” the graph representation byremoving information (data and fields) in the graph representation thatis not understandable and executable by the client interface 132. Insome embodiments, the flattened graph representation comprises aflattened JSON representation comprising a simplified and translatedversion of the original JSON representation. The presentation service114 also sends (at step 630) the client representation of the databaseworkflow 118 to the client interface 132.

The client interface 132 receives (at step 635) the clientrepresentation and displays the client representation of the databaseworkflow 118 as a client workflow 134. For example, FIG. 2 illustrates ascreenshot of a client interface 132 for presenting/displaying arequested client workflow 134, according to various embodiments. Asshown, the client workflow 134 comprise a graphical diagram thatrepresents a workflow process as an arrangement of connected geometricshapes 210, each geometric shape 210 representing a step of theworkflow.

The client interface 132 then receives (at step 640) a user inputrequesting associated content for a particular step of the clientworkflow 134. For example, the user may select (e.g., by clicking on orhovering a cursor over) a particular shape displayed in the clientinterface 132 that represents a step of the client workflow 134. Theclient interface 132 also sends (at step 640) a client request for theassociated content to the presentation service 114. In particular, theclient interface 132 sends a request for a representation of associatedcontent that is understandable and executable/displayable by the clientinterface 132.

The presentation service 114 receives (at step 645) the client requestfor the associated content and sends a database query statement to thedatabase engine 117 for the associated content. The database engine 117receives (at step 650) the database query statement for the associatedcontent, retrieves the associated content from the database 116, andsends a JSON representation of the associated content to thepresentation service 114.

The presentation service 114 then receives and translates (at step 655)the JSON representation of the associated content to a clientrepresentation of the associated content that is understandable by theclient interface 132. For example, the presentation service 114 may“flatten” the JSON representation by removing information (data andfields) in the JSON representation that is not understandable andexecutable by the client interface 132. Thus, the flattened JSONrepresentation comprises a simplified and translated version of theoriginal JSON representation. The presentation service 114 also sends(at step 655) the JSON representation of the associated content to theclient interface 132.

The client interface 132 receives (at step 660) the clientrepresentation (flattened JSON representation) of the associated contentand displays the associated content. FIG. 7 illustrates a screenshot ofa client interface 132 for displaying content associated with a clientworkflow 134, according to various embodiments. In the example of FIG. 7, the user has requested content associated with a specific shape/step710 of the client workflow 134 (e.g., by clicking on the shape/step710). In response, the content associated with the selected shape/step710 is retrieved from the database 116 and displayed in the clientinterface 132. In the example of FIG. 7 , the associated content 720comprises a webpage (including a video) that is obtained from an onlineresource. The method 600 then ends.

Section II: Platform for Searching Workflows

While workflows are effective tools for providing visual understandingsof various processes to beginners and experienced users alike,conventional workflows are not organized or related in a way that allowseasy search and retrieval of workflows relevant to a particular topic.Thus, conventional organization and storage techniques for authoredworkflows do not allow easy searching and sharing among other users,which creates substantial inefficiencies through “recreating the wheel,”for example.

Embodiments described herein provide an authoring and search platformfor creating and searching workflows using at least one predefinedtaxonomy of tags. A taxonomy comprises a hierarchy of topics/tags andsub-topics/sub-tags. Each predefined taxonomy of tags may be stored to agraph database as a database taxonomy. A database taxonomy comprises anarrangement of tag nodes and edges, the tag nodes representing tags ofthe taxonomy and the edges representing relationships between the tagnodes (such as parent-child relationships). The database taxonomy may besent to a server computer which produces a simplified internal abstractrepresentation/model of the database taxonomy (referred to as a servertaxonomy). The server computer may send a further simplified version ofthe server taxonomy (referred to as a client taxonomy) to a clientcomputer.

An author/user may interact with a client interface residing on theclient computer to create or modify client workflows comprising workflowitems (such as the overall workflow, a shape/step of the workflow, andassociated content). In some embodiments, when creating a clientworkflow, at least a first tag is received (via the client interface)from the author for at least a first workflow item. For example, a firsttag may be received and linked to the overall workflow, a specificshape/step of the workflow, and/or a specific associated content. Thefirst tag may be selected by the author from the client taxonomy(comprising a predefined taxonomy of tags) which is displayed to theauthor. In other embodiments, the first tag may comprise a new tag thatis not included in the client taxonomy.

The client interface may send client payloads to the server computerrepresenting the client workflow and the first tag linked to the firstworkflow item. In response, the server computer may produce querystatements that cause and direct the graph database to store the clientworkflow as a database workflow comprising an arrangement of workflowitem nodes (representing workflow items) and edges (representingrelationships between the nodes). The server computer may also producequery statements that cause and direct the graph database to link afirst node in the database workflow representing the first workflow itemto a first tag node in the database taxonomy representing the first tag.This process may be repeated to receive additional tags linked toadditional workflow items in the client workflow, which causesadditional nodes in the database workflow to be linked to additionalnodes in the database taxonomy within the graph database. Doing soproduces links/relationships between workflow items of a single workflowto tags within the taxonomy, these links/relationships being captured inthe graph database.

A plurality of workflows may be created in a similar manner from aplurality of different authors. Since each workflow is linked to thedatabase taxonomy in the graph database, the plurality of workflows arealso linked and related together in a meaningful way via the databasetaxonomy. For example, a first workflow may include a first workflowitem linked to a first tag in the database taxonomy and a secondworkflow may include a second workflow item also linked to the first tagin the database taxonomy. Therefore, the first workflow and the firstworkflow item are linked, via the first tag in the database taxonomy,with the second workflow and the second workflow item. Suchlinks/relationships may be built between large numbers of workflows viathe database taxonomy, which can provide powerful and efficient searchcapabilities via the database taxonomy.

In some embodiments, previously created workflows may be searched byimplementing the database taxonomy stored to the graph database. A usermay input a search tag via a client interface, which causes a search ofthe received tag within the database taxonomy on the graph database.When a matching node representing the received tag is found in thedatabase taxonomy, any workflows linked to the matching node aretraversed and returned in the search results. Without thelinks/relationships being built between the numerous workflows and thedatabase taxonomy, a search for the received tag would require traversalof all workflows stored to the database. In contrast, the embodimentherein provide a fast and efficient search of the received tag across alarge number of workflows as the search is confined to only thoseworkflows that are linked to the matching node of the database taxonomy.This enables a search solution that is scalable as the number ofworkflows stored to the database continually increases.

Authoring and Searching Environment

FIG. 8 illustrates an authoring and search platform environment 800configured to implement one or more aspects of the present invention.The authoring and search platform environment 800 enables authoring andsearching of workflows to a graph database using a tag taxonomy. Theauthoring and search platform environment 800 comprises some componentsthat correspond to components of the authoring platform environment 100shown in FIG. 1 and are not discussed in detail here. The components andfeatures of the authoring and search platform environment 800 that aredifferent from the components and features described in relation to theauthoring platform environment 100 of FIG. 1 are discussed below.

As shown, the environment 800 includes at least one client computer 130(e.g., 130A-130N), a server computer 110, and at least one contentserver 140 (e.g., 140A-140N) coupled via a network 120. Each clientcomputer 130 hosts and executes a client interface engine 132, theserver computer 110 hosts and executes an authoring service engine 812and a search service engine 814. The server computer 110 is also coupledto a graph database 116 comprising a database engine 117 that organizesand stores database workflows 118.

As shown in FIG. 8 , the client computer 130, server computer 110, andthe graph database 116 each stores (e.g., in memory or storage) aseparate and distinct version/representation of a predefined taxonomy. Ataxonomy comprises a hierarchical arrangement of topics/tags, where atag may be a “child” of another tag to form a hierarchy of topics/tagsand sub-topics/sub-tags. A taxonomy may be created for an overall topic,whereby each tag or sub-tag in the taxonomy may specify a particulartopic or sub-topic of the overall topic. For example, a taxonomy may becreated for all software products of a company (the overall topic),whereby sub-topics may include office software, multimedia software,web-based software, and security software. Each sub-topic may alsoinclude further sub-topics, such as names of particular softwareproducts within the sub-topic, and so forth. The resulting taxonomy oftags may include tags and sub-tags corresponding to each of the topicsand sub-topics.

The graph database 116 stores a database taxonomy 851 comprising anarrangement of tag nodes and edges, the tag nodes representingtopics/tags of the taxonomy and the edges representing relationshipsbetween the topics/tags (such as parent-child relationships). Thedatabase taxonomy 851 may comprise a persistent/permanent record of atag taxonomy in the form of nodes, relationships, and property records(as well as database artifacts such as indexes and constraints). Thedatabase taxonomy may also exist in an expanded form in a memory of theserver computer 110 when the database engine 117 is activated, wherebythe form of the database taxonomy 851 is configured to provide anoptimal performance database environment after the expansion.

FIG. 9 illustrates a conceptual diagram of a database taxonomy 851stored in the graph database 116 of FIG. 8 , according to variousembodiments. The database taxonomy 851 represents a taxonomy of tagscomprising a hierarchy of topics/tags and sub-topics/sub-tags. Ataxonomy may be created for an overall topic, whereby each tag orsub-tag in the taxonomy may specify a particular topic or sub-topic ofthe overall topic. One or more predefined taxonomies may be stored tothe graph database 116 as one or more database taxonomies 851. As shown,a database taxonomy 851 represents a taxonomy of tags as a hierarchicalarrangement of tag nodes 910 and tag edges 920. The tag nodes 910represent topics/tags of the taxonomy and the tag edges 910 representrelationships between the tag nodes 910 (such as parent-childrelationships or topic/sub-topic relationships). A top tag node 910 ofthe database taxonomy 851 may represent the overall topic/tag (such asall software products of a company), and child tag nodes 910 mayrepresent sub-topics/sub-tags of the overall topic/tag (such as officesoftware, multimedia software, web-based software, etc.). Each child tagnodes 910 may comprise zero or more grand-child nodes 910 representingsub-topics of the child tag nodes 910 (such as names of particularsoftware products within the sub-topic), and so forth.

The server computer 110 stores a server taxonomy 852 that is asimplified abstract internal representation/model of the databasetaxonomy 851. The server taxonomy 852 may comprise a series of temporaryobject records that create an abstract model of the database taxonomy851 for internal use by the server computer 110. The server taxonomy 852is created from facets of the database taxonomy 851 that are exposed bydatabase queries. Thus, the server taxonomy 852 may comprise facetedrepresentations of the database taxonomy 851 that are exposed viadatabase queries to create the server taxonomy 852 (comprising a seriesof temporary abstract models of facets of the database taxonomy 851).

The server computer 110 may send a further simplified version of theserver taxonomy 852 (referred to as a client taxonomy 853) to eachclient computer 130 which stores the client taxonomy 853. A clienttaxonomy 853 may comprise a simplified version of the server taxonomy852 as well as the database taxonomy 851. For example, the clienttaxonomy 853 may comprise a flattened version of the server taxonomy 852and the database taxonomy 851 with hierarchical information removed.Thus, the client taxonomy 853 may comprise a flattened list of taxonomytags instead of a hierarchy of taxonomy tags. In some embodiments, aclient taxonomy 853 exists in transit as a JavaScript object in a memoryof the client computer 130 and is displayed to a user in the form ofrendered HTML markup.

Each different version of the taxonomy may comprise a different dataformat and syntax that is appropriate for the computing device on whichthe taxonomy version is stored. For example, the client taxonomy 853 isunderstandable and displayable by the client interface 132 residing onthe client computer 130, whereas the database taxonomy 851 is notunderstandable and displayable by the client interface 132. Theauthoring service 812 residing on the server computer 110 may produce aserver taxonomy 852 to assist translations between the database taxonomy851 on the database 116 and the client taxonomy 853 on the clientcomputer 130.

An author/user may interact with a client interface 132 executing on theclient computer 130 to create and/or modify a client workflow 134 (asdescribed in Section I). The client interface 132 may comprise acombined web-browser and workflow editor application that interacts withthe service engines of the server computer 110 (such as authoringservice engine 812 and search service engine 814). The author/user mayalso interact with the client interface 132 to input a tag for aspecific workflow item (such as the overall workflow, a shape/step ofthe workflow, and associated content), whereby the client interface 132determines that the specified workflow item is linked to the receivedtag.

FIG. 10 illustrates a screenshot of a client interface 132 for linking atag with a workflow item, according to various embodiments. Via theclient interface 132, the author/user may first select a specificworkflow item of the client workflow 134 to link to a tag, such as theoverall client workflow 134, a shape/step 210 of the workflow, orassociated content. For example, the author/user may select a particularshape/step 210 of the client workflow 134 to link to a tag. In response,the client interface 132 may display the client taxonomy 853 near theselected shape/step 210, for example as a list of selectable tags 1010.The user may then select a tag from the displayed client taxonomy 853(the list of selectable tags 1010), or enter a new tag not included inthe client taxonomy 853.

The client interface 132 then sends client payloads representing theuser interactions with the client workflow 134 to the authoring service812 residing on the server computer 110. The client payload may comprisea set of client requests and client metadata representing the userinteractions with the client workflow 134. As discussed in Section I,the client metadata may comprise different types of metadata includinggeneral metadata, context metadata, and content metadata. In someembodiments, the client metadata further includes tag metadata thatspecifies a workflow item and a received tag that is linked with theworkflow item.

The authoring service 812 receives the client payloads representing theuser interactions for a client workflow 134 to produce an internalserver workflow 115 representation of the client workflow 134. Asdiscussed in Section I, based on the received client payload and theinternal server workflow 115, the authoring service 812 produces a setof database query statements that cause and direct the database engine117 of the database 116 to store the client workflow 134 as a databaseworkflow 118 comprising a set of workflow item nodes (representingworkflow items) and edges (representing relationships between thenodes). Note that a workflow item node comprises a node of a particulardatabase workflow 118, whereas a tag node comprises a node of thedatabase taxonomy 851.

In some embodiments, in response to the tag metadata received in theclient payload, the authoring service 812 performs several additionaloperations. For illustrative purposes, it is assumed that the receivedtag metadata specifies a first workflow item in a first client workflow134 that corresponds to a first workflow item in a first server workflow115 and a first workflow item node (representing a first workflow item)in a first database workflow 118. It is also assumed that the receivedtag metadata specifies a first tag in the client taxonomy 853 that islinked to the first workflow item in the first client workflow 134, thefirst tag in the client taxonomy 853 corresponding to a first tag in theserver taxonomy 852 and a first tag node (representing the first tag) inthe database taxonomy 853.

The authoring service 812 may first produce a link/relationship betweenthe server taxonomy 852 and the first server workflow 115 according tothe received tag metadata. In particular, the authoring service 812 mayproduce a link/relationship between the first tag in the server taxonomy852 and the first workflow item in the first server workflow 115according to the received tag metadata. In some cases, the receivedfirst tag comprises a new tag that is not included in the clienttaxonomy 853, and is also not included in the server taxonomy 852 or thedatabase taxonomy 851. In these cases, the authoring service 812 mayfirst dynamically create and insert a new tag in the server taxonomy 852representing the received first tag. In some embodiments, all new tagsare inserted in the server taxonomy 852 at a same flat level and are notinterconnected with other tags of the server taxonomy 852. The authoringservice 812 may then produce a link/relationship between the new tag inthe server taxonomy 852 and the first workflow item in the first serverworkflow 115.

In addition, based on the link/relationship created between the betweenthe server taxonomy 852 and the first server workflow 115, the authoringservice 812 produces a set of linking query statements that cause anddirect the graph engine 117 to produce a similar link/relationshipbetween the database taxonomy 851 and the first database workflow 118that reflects the received tag metadata. In particular, the set oflinking query statements may cause and direct the graph engine 117 toproduce a link between the first tag node (representing the first tag)in the database taxonomy 851 to the first node (representing the firstworkflow item) in the first database workflow 118.

In the case where the received first tag comprises a new tag notincluded in the database taxonomy 851, the set of linking querystatements cause and direct the graph engine 117 to dynamically createand insert a new tag node (representing the first tag) in the databasetaxonomy 851. Thus, the database taxonomy 851 may be considered a“living” taxonomy whereby new tags may be dynamically added to thetaxonomy. In some embodiments, all new tag nodes representing new tagsare inserted in the database taxonomy 851 at a same flat level and arenot interconnected with other tags of the database taxonomy 851. The setof linking query statements may further cause and direct the graphengine 117 to produce a link between the new tag node (representing thefirst tag) in the database taxonomy 851 to the first node (representingthe first workflow item) in the first database workflow 118.

The graph engine 117 receives and executes the set of database querystatements (including the set of linking query statements) to create ormodify the first database workflow 118 corresponding to the first clientworkflow 134 and produce a link between a first tag node or new tag node(representing the first tag) in the database taxonomy 851 to the firstworkflow item node (representing the first workflow item) in the firstdatabase workflow 118.

The above process may be repeated to receive additional tags linked toadditional workflow items in the client workflow 134, which causesadditional work item nodes in the database workflow 118 to be linked toadditional tag nodes in the database taxonomy 851 within the graphdatabase 116. Also, a plurality of client workflows 134 and databaseworkflows 118 may be created in a similar manner from a plurality ofdifferent authors. Since each corresponding database workflow 118 islinked to the database taxonomy 851, a large number of databaseworkflows 118 are also linked and related together in a meaningful wayvia the database taxonomy 851 to provide powerful and efficient searchcapabilities via the database taxonomy 851.

FIG. 11 illustrates a conceptual diagram of two database workflows 118linked to a database taxonomy 851, according to various embodiments. Afirst database workflow 1110 corresponds to a first client workflow 134and a second database workflow 1150 corresponds to a second clientworkflow 134. A first tag node 1101 represents a first tag of thedatabase taxonomy 851 and a second tag node 1102 represents a second tagof the database taxonomy 851. FIG. 11 also shows a plurality of linkingedges 1103-1106. As used herein, a linking edge connects a tag node ofthe database taxonomy 851 to a workflow item node of a database workflow118 and represents a linking relationship between the tag node and theworkflow item node.

The first database workflow 1110 comprises a workflow node 1115(representing the overall first client workflow), a first step node 1120(representing a first step of the first client workflow), a second stepnode 1125 (representing a second step of the first client workflow), athird step node 1120 (representing a third step of the first clientworkflow), and so forth. Also, a content node 1122 is associated withthe first step node 1120 (representing content associated with the firststep of the first client workflow). The second database workflow 1150comprises a workflow node 1155 (representing the overall second clientworkflow), a first step node 1160 (representing a first step of thesecond client workflow), a second step node 1165 (representing a secondstep of the second client workflow), and so forth. Also, a content node1170 is associated with the second step node 1165 (representing contentassociated with the second step of the second client workflow).

In the example of FIG. 11 , a first tag (represented by the first tagnode 1101) is received from a user (via the client interface 132) forthe first step of the first client workflow (represented by the firststep node 1120), which causes the database engine 117 to create a firstlinking edge 1103 that links/connects the first tag node 1101 to thefirst step node 1120. A second tag (represented by the second tag node1102) is also received for the content associated with the first step ofthe first client workflow (represented by the content node 1122associated with the first step node 1120), which causes the databaseengine 117 to create a second linking edge 1104 that links/connects thesecond tag node 1102 to the content node 1122.

Further, a first tag (represented by the first tag node 1101) isreceived from a user (via the client interface 132) for the overallsecond client workflow (represented by the workflow node 1155), whichcauses the database engine 117 to create a third linking edge 1105 thatlinks/connects the first tag node 1101 to the workflow node 1155. Asecond tag (represented by the second tag node 1102) is also receivedfor the second step of the second client workflow (represented by thesecond step node 1165), which causes the database engine 117 to create afourth linking edge 1106 that links/connects the second tag node 1102 tothe second step node 1165.

Note that a work item node can also be linked to multiple tag nodes (notshown) if multiple tags are received for the work item. Also, the firsttag node 1101 and the second tag node 1102 shown in FIG. 11 mayrepresent predefined tags that were previously included in the databasetaxonomy 851 or new tags that were not previously included in thedatabase taxonomy 851 (whereby the tag nodes 1101 and 1102 aredynamically created and inserted into the database taxonomy 851 by thedatabase engine 117). Thus, the database taxonomy 851 may be considereda “living” taxonomy whereby new tags may be dynamically added to thetaxonomy.

As shown, the linking edges 1103-1106 represent links/relationshipsbuilt between the first database workflow 1110 and the second databaseworkflow 1150 via the database taxonomy 851. In particular, the firstdatabase workflow 1110 and the second database workflow 1150 are linkedvia the first tag node 1101 and the second tag node 1102 of the databasetaxonomy 851. In general, such links/relationships between the databaseworkflows 118 built through the database taxonomy 851 allows a largenumber of database workflows 118 to be quickly and efficiently searched.

Authoring and Storing Workflows Based on a Taxonomy

FIG. 12 illustrates a flow diagram of method steps for authoring andstoring workflows based on a taxonomy, according to various embodiments.Although the method steps are described in conjunction with the systemsof FIGS. 1-4 and 7-11 , persons skilled in the art will understand thatany system configured to perform the method steps, in any order, iswithin the scope of the invention. In some embodiments, the method 1200may be performed by the client interface 132 executing on a clientcomputer 130, an authoring service engine 812 executing on a servercomputer 110, and a database engine 117 executing on a database 116.Some steps of the method 1200 are similar to steps of the method 500 ofFIG. 5 and are not discussed in detail here. Prior to the method 1200,it is assumed that a database taxonomy 851 representing a predefinedtaxonomy of topics/tags is stored to graph database 116.

The method 1200 begins when the client interface 132 establishes anauthenticated connection with the authoring service 812 via a network120 (at step 1205) and sends a request to the authoring service 812 fora client representation (client taxonomy 853) of the database taxonomy851 that is understandable and displayable by the client interface 132.In response, the authoring service 812 receives (at step 1210) therequest for the client taxonomy 853 and retrieves the current databasetaxonomy 851 from the graph database 116. In some embodiments, theclient interface 132 requests the client taxonomy 853 each time theclient interface 132 connects to the authoring service 812 and theauthoring service 812 retrieves the most recent and up-to-date clientrepresentation of the database taxonomy 851 (including the most recentlyadded new tags) is received by the client interface 132.

Based on the database taxonomy 851, the authoring service 812 produces(at step 1215) a server taxonomy 852 and the requested client taxonomy853. The server taxonomy 852 may comprise an abstract internalrepresentation of the database taxonomy 851. The authoring service 812may then produce the client taxonomy 853 based on the server taxonomy852. The client taxonomy 853 may comprise a simplified version of theserver taxonomy 852 as well as the database taxonomy 851. For example,the client taxonomy 853 may comprise a flattened version of the servertaxonomy 852 and the database taxonomy 851 with hierarchical informationremoved. Thus, the client taxonomy 853 may comprise a flattened list oftaxonomy tags instead of a hierarchy of taxonomy tags. The authoringservice 812 also sends (at step 1215) the client taxonomy 853 to theclient interface 132. The client interface 132 receives and locallystores (at step 1220) the client taxonomy 853.

The client interface 132 then receives (at step 1225) a user interactioncreating a new client workflow 134 or modifying a client workflow 134.As shown in FIG. 2 , the received user interaction may comprise anadding, removing, or editing of one or more geometric shapes 210representing steps and/or one or more connections 220 representingrelationships between the steps. As shown in FIG. 10 , the received userinteraction may comprise receiving a tag linked to a specific workflowitem (such as the overall workflow, a shape/step of the workflow, andassociated content). The received tag may comprise a predefined tagpreviously included in the client taxonomy 853 or new tag not previouslyincluded in the client taxonomy 853.

The client interface 132 then produces and sends (at step 1230) a clientpayload to the authoring service 812, the client payload representingthe received user interaction. The client payload may comprise clientrequests and client metadata representing the received user interactionwith the client workflow 134. The client metadata may comprise differenttypes of metadata including general metadata, context metadata, contentmetadata, and tag metadata. The tag metadata may specify a workflow item(such as the overall workflow, a step, or associated content) and areceived tag that is linked with the workflow item. In some embodiments,the client payload is formatted in the JSON format.

The authoring service 812 receives (at step 1235) the client payloadfrom the client interface 132 and creates or modifies an internal serverworkflow 115 corresponding to the client workflow 134 and modifies theserver taxonomy 852 based on the received client payload. In response tothe received tag metadata, the authoring service 812 also performsseveral additional operations. For example, it is assumed that thereceived tag metadata specifies a first workflow item in a clientworkflow 134 that corresponds to a first workflow item in a serverworkflow 115 and a first workflow item node (representing the firstworkflow item) in a database workflow 118. It is also assumed that thereceived tag metadata specifies a first tag in the client taxonomy 853that is linked to the first workflow item in the client workflow 134,the first tag in the client taxonomy 853 corresponding to a first tag inthe server taxonomy 852 and a first tag node (representing the firsttag) in the database taxonomy 853. The authoring service 812 may firstproduce a link between the server taxonomy 852 and the server workflow115 according to the received tag metadata. In particular, the authoringservice 812 may produce a link between the first tag in the servertaxonomy 852 and the first workflow item in the server workflow 115. Ifthe first tag is a new tag, the authoring service 812 may dynamicallycreate a new tag in the server taxonomy 852 representing the receivedfirst tag and then produce a link between the new tag in the servertaxonomy 852 and the first workflow item in the server workflow 115.

Based on the received client payload and the modifications to the serverworkflow 115 and the server taxonomy 852, the authoring service 812 alsogenerates (at step 1240) a set of database query statements that directsthe database engine 117 to create or modify a database workflow 118(corresponding to the client workflow 134 and the server workflow 115)and modify the graph taxonomy 851. For example, the authoring service812 may translate the modifications made to the server workflow 115 to aset of database query statements that produce corresponding/equivalentmodifications to the graph database workflow 118. In addition, at step1240, based on the received client payload and link/relationship createdbetween the between the server taxonomy 852 and the server workflow 115,the authoring service 812 produces a set of linking query statementsthat cause and direct the graph engine 117 to produce a similarlink/relationship between the database taxonomy 851 and the databaseworkflow 118 to reflect the received tag metadata. For example, the setof linking query statements may cause and direct the graph engine 117 toproduce a link between the first tag node (representing the first tag)in the database taxonomy 851 to the first workflow item node(representing the first workflow item) in the database workflow 118. Inthe case where the received first tag comprises a new tag not includedin the database taxonomy 851, the set of linking query statements causeand direct the graph engine 117 to dynamically create and insert a newtag node (representing the first tag) in the database taxonomy 851 andto produce a link between the new tag node (representing the first tag)in the database taxonomy 851 to the first workflow item node(representing the first workflow item) in the database workflow 118. Theauthoring service 812 also sends (at step 1240) the set of databasequery statements to the database engine 117, the set of database querystatements including the set of linking query statements.

The database engine 117 receives and executes (at step 1245) the set ofdatabase query statements to create or modify a database workflow 118corresponding to the client workflow 134. In addition, the graph engine117 receives and executes the set of linking query statements to producea link between a first tag node (representing the first tag) in thedatabase taxonomy 851 to the first workflow item node (representing thefirst workflow item) in the database workflow 118. In the case where thefirst tag comprises a new tag, the graph engine 117 executes the set oflinking query statements to dynamically create and insert a new tag node(representing the first tag) in the database taxonomy 851 and to producea link between the new tag node to the first workflow item node in thedatabase workflow 118.

The client interface 132 then determines (at step 1250) whether a userinput is received for quitting the session or logging off the authoringservice 812. If so, the method 1200 ends. If not, the method 1200continues at step 1225 where the client interface 132 receives a newuser interaction with the client workflow 134.

Overall, multiple iterations of the method 1200 are performed to processmultiple user interactions that create and modify the client workflow134 and to receive additional tags linked to additional workflow itemsin the client workflow 134, which thereby causes additional work itemnodes in the database workflow 118 to be linked to additional tag nodesin the database taxonomy 851 within the graph database 116. Also, aplurality of client workflows 134 and database workflows 118 may becreated from a plurality of different authors using the method 1200 toproduce links/relationships between a plurality of database workflows118 via the database taxonomy 851.

Searching Workflows Based on a Taxonomy

In some embodiments, previously created database workflows 118 may besearched by implementing the database taxonomy 851 stored to the graphdatabase 116.

FIG. 13 illustrates a flow diagram of method steps for searching andpresenting workflows based on a taxonomy, according to variousembodiments. Although the method steps are described in conjunction withthe systems of FIGS. 1-4 and 7-11 , persons skilled in the art willunderstand that any system configured to perform the method steps, inany order, is within the scope of the invention. In some embodiments,the method 1300 may be performed by the client interface 132 executingon a client computer 130, a search service engine 814 and a presentationservice engine 114 executing on a server computer 110, and a databaseengine 117 executing on a database 116. Some steps of the method 1300are similar to steps of the method 600 of FIG. 6 and are not discussedin detail here.

The method 1300 begins when the client interface 132 establishes anauthenticated connection with the search service 814 via a network 120(at step 1305). The client interface 132 then receives (at step 1310) auser input specifying a search tag and sends the search tag to thesearch service 814. A search tag may comprise one or more text terms.The client interface 132 may translate the search tag to an HTTP RESTfulweb-server request with a parameter (the search tag) which is then sentto the search service 814.

The search service 814 receives (at step 1315) the request specifyingthe search tag and produces a set of database query statements thatcause and direct the database engine 117 to return workflow items (suchas overall workflows, a step in a workflow, and/or associated content)relevant to the search tag. In particular, the database query statementsmay direct the database engine 117 to locate and identify a matching tagnode in the database taxonomy 851, the matching tag node representing atag matching the search tag and to begin the search at the matching tagnode. The database query statements may also direct the database engine117 to begin the traversing of work item nodes of database workflows 118at each work item node linked to the matching tag node to identify workitem nodes relevant to the search tag. Thus, by producing focuseddatabase query statements that confine the search and start thetraversing operations at work item nodes linked to the matching tagnode, an efficient search of relevant work item nodes across a largenumber of database workflows 118 may be performed.

The database query statements (produced at step 1315) may further directthe database engine 117 to traverse the work item nodes and returninformation for all relevant work item nodes (such as author, title,and/or brief description). For example, relevant work item nodes may bedefined as work item nodes linked (by a linking edge) to the matchingtag node. Also, for a step node (representing a step) that is linked tothe matching tag node, a relevant node may also be defined to includethe workflow node representing the overall workflow containing the step.For a content node (representing content associated with a step) that islinked to the matching tag node, a relevant node may also be defined toinclude a step node (representing a step associated with the content)and a workflow node representing the overall workflow containing thestep and the associated content.

The database engine 117 receives and executes (at step 1320) the set ofdatabase query statements to perform a search process to identify andcollect information for workflow items relevant to the search tag. Inparticular, the database engine 117 begins a search at the matching tagnode in the database taxonomy 851 and begin a traversing process at eachwork item node linked to the matching tag node to identify and collectinformation on relevant work item nodes. When traversing the work itemnodes, the database engine 117 moves from one connected work item nodeto another connected work item node to analyze and collect informationon each work item node (such as author, title, and/or briefdescription). An example of the search process performed at step 1320 isshown in FIG. 14 .

FIG. 14 illustrates a conceptual diagram of a search process based onthe database taxonomy 851 illustrated in FIG. 11 , according to variousembodiments. FIG. 14 shows some components similar to components shownin FIG. 11 and are not discussed in detail here. In the example of FIG.14 , the received search tag matches the second tag represented by thesecond tag node 1102 of the database taxonomy 851. Therefore the searchservice 814 begins the search process at the second tag node 1102(indicated by the bold node in FIG. 14 ). The search service 814 thenbegins a traversing process at each work item node linked to the secondtag node 1102. A first traversing process (indicated by the bold dashednodes and lines in FIG. 14 ) may begin at the content node 1122 that islinked to the second tag node 1102 by the second linking edge 1104. Thesearch service 814 traverses work item nodes connected to the contentnode 1122 to identify other relevant work item nodes. For the contentnode 1122 (representing content associated with a first step of thefirst client workflow), relevant nodes include the first step node 1120(representing the first step of the first client workflow) and theworkflow node 1115 (representing the first client workflow). Whentraversing the work item nodes, the search service 814 may collectinformation for each relevant work item node. A second traversingprocess (indicated by the dashed nodes and lines in FIG. 14 ) may beginat the second step node 1165 that is linked to the second tag node 1102by the fourth linking edge 1106. The search service 814 traverses workitem nodes connected to the second step node 1165 to identify otherrelevant work item nodes. For the second step node 1165 (representing asecond step of the second client workflow), a relevant node includes theworkflow node 1155 (representing the second client workflow). Whentraversing the work item nodes, the search service 814 may collectinformation for each relevant work item node.

Based on the information collected for the relevant work item nodes, thedatabase engine 117 then produces and sends a set of search results (atstep 1325) to the search service 814. The set of search results mayinclude, for each relevant work item node, the type of work item thatthe node represents (such as overall workflow, step, or associatedcontent). The set of search results may also include the informationcollected for each relevant work item node, such as the author, title,and/or brief description. The set of search results may also include,for each relevant step node representing a step, the information for theworkflow that contains the step. The set of search results may furtherinclude, for each relevant content node representing content associatedwith a step of a workflow, the information for the step and the workflowthat contains the step.

The search service 814 then receives (at step 1330) the set of searchresults and sends the set of search results to the client interface 132.The client interface 132 receives and displays (at step 1335) the set ofsearch results to the user. The client interface 132 then receives (atstep 1340) a user input requesting a particular database workflow 118(corresponding to a previously created client workflow 134) listed inthe set of search results and sends a client request for the desireddatabase workflow 118 to the presentation service 114. The method 1300may then continue at step 620 of FIG. 6 to retrieve and presenting therequested database workflow 118.

In sum, an authoring platform 100 is provided for authoring a workflowcomprising a sequence of steps for performing a process. An author/usermay create a client workflow 134 through interactions with a clientinterface 132, the client workflow 134 comprising an arrangement ofconnected geometric shapes 210, the geometric shapes 210 representingsteps of the workflow and the connections 220 representing relationshipsbetween the shapes/steps. Content may be associated with one or moreshapes/steps 210 of the client workflow 134. The associated content maycomprise a wide range of content, including online content retrievedfrom an online resource via a network 120. An authoring service 112executing on a server computer 110 receives user interactions forcreating or modifying the client workflow 134 from the client interface132 via the network 120. The authoring service 112 translates thereceived user interactions to a set of database query statements thatcause and direct a database engine 117 of the database 116 to store ormodify the client workflow 134 as a database workflow 118. The databaseengine 117 receives and executes the set of database query statements tocreate or modify the database workflow 118. The database workflow 118may comprise a graph structure that represents the client workflow 134as an arrangement of nodes and edges, the nodes representing steps ofthe client workflow 134 and the edges representing relationships betweenthe steps. A client workflow 132 that is created by the authoringplatform 100 and stored to the database 116 as a corresponding databaseworkflow 118 may be later retrieved from the database 116 and displayedat a client interface 132. A database workflow 118 stored to thedatabase 116 may be accessed by any client computer 130 executing aclient interface 132 via the network 120. Thus, the authoring platform100 enables web-based authoring and access to database workflows 118that allows broad collaboration and distribution of the databaseworkflows 118.

At least one advantage of the disclosed technique is that it enablesauthoring of workflows that may include a wide range of content,including online content. Another advantage of the disclosed techniqueis that it enables efficient storing and retrieval of workflows using agraph database.

In sum, an authoring and search platform is provided for creating andsearching workflows using a taxonomy of tags. A database taxonomycomprises an arrangement of tag nodes and edges, the tag nodesrepresenting tags of the taxonomy and the edges representingrelationships between the tag nodes (such as parent-childrelationships). A simplified version of the database taxonomy (clienttaxonomy) may be loaded to a client computer. An author may interactwith a client interface to create or modify a client workflow wherein atleast a first tag is received and linked to at least a first workflowitem. The client interface sends client payloads to the server computerrepresenting the client workflow and the first tag linked to the firstworkflow item. The server computer produces query statements that directthe graph database to store the client workflow as a database workflowand link a first node in the database workflow representing the firstworkflow item to a first tag node in the database taxonomy representingthe first tag. This process may be repeated to receive additional tagslinked to additional workflow items in the client workflow, which causesadditional nodes in the database workflow to be linked to additionalnodes in the database taxonomy within the graph database. A plurality ofworkflows may be created in a similar manner to link the plurality ofworkflows to the database taxonomy in the graph database. The createdand linked workflows may be searched by implementing the databasetaxonomy stored to the graph database.

At least one advantage of the disclosed technique is that fast andefficient searches of a large number of workflows linked to a taxonomyof tags may be performed.

FIG. 15 illustrates an example server computer 110 of FIGS. 1 and 8 ,according to various embodiments. The server computer 110 comprises atleast one processor 1502 coupled to input/output (I/O) devices 1504 andto a memory unit 1506. The server computer 110 is coupled to a graphdatabase 116 comprising a database engine 117 that organizes and storesdatabase workflows 118 and at least one database taxonomy 851. Theserver computer 110 is also coupled to a network 120 via a networkinterface (not shown). The network 120 may comprise any technicallyfeasible communications or information network, wired or wireless, thatallows data exchange, such as a wide area network (WAN), a local areanetwork (LAN), a wireless (Wi-Fi) network, and/or the Internet, amongothers.

Processor 1502 may be a central processor (CPU), a graphics processor(GPU), an application-specific integrated circuit (ASIC), afield-programmable gate array (FPGA), and so forth. Processor 1502 mayalso be a combination of different processors, such as a CPU configuredto operate in conjunction with a GPU, or many CPUs configured to worktogether through cloud computing. In general, processor 1502 may be anytechnically feasible processing device or hardware unit capable ofprocessing data and executing software applications and program code.The processor 1502 executes the software and performs the functions andoperations set forth in the embodiments described herein.

Memory 1506 is configured to store software application(s) and data.Instructions from the software constructs within the memory 1506 areexecuted by processors 1502 to enable the inventive operations andfunctions described herein. Memory 1506 may include a hard disk, arandom access memory (RAM) module, a flash memory unit, or any othertype of memory unit or combination thereof. Processor 1502 and I/Odevices 1504 are configured to read data from and write data to memory1506. The memory 1506 may store an authoring service engine 112 and 812,presentation service engine 114, search service engine 814, at least oneserver workflow 115, and at least one server taxonomy 852.

I/O devices 1504 are also coupled to memory 1506 and may include devicescapable of receiving input, such as a keyboard, a mouse, a trackball,and so forth, as well as devices capable of providing output, such as adisplay, speaker, and so forth. Additionally, I/O devices may includedevices capable of both receiving input and providing output, such as atouchscreen, a universal serial bus (USB) port, and so forth.

FIG. 16 illustrates an example client computer 130 of FIGS. 1 and 8 ,according to various embodiments. The client computer 130 may be aworkstation, a laptop computer, a tablet, hand-held or mobile device, orany other device capable of performing embodiments described herein. Theclient computer 130 comprises at least one processor 1602 coupled toinput/output (I/O) devices 1604 and to a memory unit 1606. The clientcomputer 130 is also coupled to a network 120 via a network interface(not shown).

Processor 1602 may be a central processor (CPU), a graphics processor(GPU), an application-specific integrated circuit (ASIC), afield-programmable gate array (FPGA), and so forth. Processor 1602 mayalso be a combination of different processors, such as a CPU configuredto operate in conjunction with a GPU, or many CPUs configured to worktogether through cloud computing. In general, processor 1602 may be anytechnically feasible processing device or hardware unit capable ofprocessing data and executing software applications and program code.The processor 1602 executes the software and performs the functions andoperations set forth in the embodiments described herein.

Memory 1606 is configured to store software application(s) and data.Instructions from the software constructs within the memory 1606 areexecuted by processors 1602 to enable the inventive operations andfunctions described herein. Memory 1606 may include a hard disk, arandom access memory (RAM) module, a flash memory unit, or any othertype of memory unit or combination thereof. Processor 1602 and I/Odevices 1604 are configured to read data from and write data to memory1606. The memory 1606 may store a client interface engine 132, at leastone client workflow 132, and at least one client taxonomy 853.

I/O devices 1604 are also coupled to memory 1606 and may include devicescapable of receiving input from an end-user, such as a keyboard, amouse, a trackball, and so forth, as well as devices capable ofproviding output to an end-user, such as a display, speaker, and soforth. Additionally, I/O devices may include devices capable of bothreceiving input and providing output, such as a touchscreen, a universalserial bus (USB) port, and so forth. In particular, the I/O devices mayfurther include a display monitor that displays the client interface132, client workflows 132, and client taxonomy 853.

The descriptions of the various embodiments have been presented forpurposes of illustration, but are not intended to be exhaustive orlimited to the embodiments disclosed. Many modifications and variationswill be apparent to those of ordinary skill in the art without departingfrom the scope and spirit of the described embodiments. Terms such as“first” and “second” (e.g., first work item, second work item) are usedto indicate particular instances and do not indicate a sequentialordering unless specifically stated.

Aspects of the present embodiments may be embodied as a system, methodor computer program product. Accordingly, aspects of the presentdisclosure may take the form of an entirely hardware embodiment, anentirely software embodiment (including firmware, resident software,micro-code, etc.) or an embodiment combining software and hardwareaspects that may all generally be referred to herein as a “circuit,”“module” or “system.” Furthermore, aspects of the present disclosure maytake the form of a computer program product embodied in one or morecomputer readable medium(s) having computer readable program codeembodied thereon.

Any combination of one or more computer readable medium(s) may beutilized. The computer readable medium may be a computer readable signalmedium or a computer readable storage medium. A computer readablestorage medium may be, for example, but not limited to, an electronic,magnetic, optical, electromagnetic, infrared, or semiconductor system,apparatus, or device, or any suitable combination of the foregoing. Morespecific examples (a non-exhaustive list) of the computer readablestorage medium would include the following: an electrical connectionhaving one or more wires, a portable computer diskette, a hard disk, arandom access memory (RAM), a read-only memory (ROM), an erasableprogrammable read-only memory (EPROM or Flash memory), an optical fiber,a portable compact disc read-only memory (CD-ROM), an optical storagedevice, a magnetic storage device, or any suitable combination of theforegoing. In the context of this document, a computer readable storagemedium may be any tangible medium that can contain, or store a programfor use by or in connection with an instruction execution system,apparatus, or device.

Aspects of the present disclosure are described above with reference toflowchart illustrations and/or block diagrams of methods, apparatus(systems) and computer program products according to embodiments of thedisclosure. It will be understood that each block of the flowchartillustrations and/or block diagrams, and combinations of blocks in theflowchart illustrations and/or block diagrams, can be implemented bycomputer program instructions. These computer program instructions maybe provided to a processor of a general purpose computer, specialpurpose computer, or other programmable data processing apparatus toproduce a machine, such that the instructions, which execute via theprocessor of the computer or other programmable data processingapparatus, enable the implementation of the functions/acts specified inthe flowchart and/or block diagram block or blocks. Such processors maybe, without limitation, general purpose processors, special-purposeprocessors, application-specific processors, or field-programmableprocessors or gate arrays.

The flowchart and block diagrams in the figures illustrate thearchitecture, functionality, and operation of possible implementationsof systems, methods and computer program products according to variousembodiments of the present disclosure. In this regard, each block in theflowchart or block diagrams may represent a module, segment, or portionof code, which comprises one or more executable instructions forimplementing the specified logical function(s). It should also be notedthat, in some alternative implementations, the functions noted in theblock may occur out of the order noted in the figures. For example, twoblocks shown in succession may, in fact, be executed substantiallyconcurrently, or the blocks may sometimes be executed in the reverseorder, depending upon the functionality involved. It will also be notedthat each block of the block diagrams and/or flowchart illustration, andcombinations of blocks in the block diagrams and/or flowchartillustration, can be implemented by special purpose hardware-basedsystems that perform the specified functions or acts, or combinations ofspecial purpose hardware and computer instructions.

While the preceding is directed to embodiments of the presentdisclosure, other and further embodiments of the disclosure may bedevised without departing from the basic scope thereof, and the scopethereof is determined by the claims that follow.

The invention claimed is:
 1. A computer-implemented method for authoringa workflow, the method comprising: receiving, at a computer, a firstworkflow that includes a first representation for a first step of thefirst workflow; generating, at the computer, a set of database queriesthat, when executed, produce a second workflow that includes a secondrepresentation for the first step of the first workflow that isdifferent than the first representation; and transmitting the set ofdatabase queries to a database for execution.
 2. Thecomputer-implemented method of claim 1, wherein the first workflow isreceived from a web-based interface associated with a second computer.3. The computer-implemented method of claim 1, further comprisingreceiving, at the computer, online content associated with at least oneoperation of the first workflow.
 4. The computer-implemented method ofclaim 3, wherein the online content comprises content retrieved from anonline resource specified by a URL.
 5. The computer-implemented methodof claim 4, wherein the content is retrieved from the online resourcethrough a service that extracts metadata from the online resource. 6.The computer-implemented method of claim 1, wherein: a plurality ofconnections in the first workflow indicate a sequential ordering of aplurality of operations included in the first workflow; and a pluralityof edges in the second workflow indicate a sequential ordering of aplurality of operations included in the second workflow.
 7. Thecomputer-implemented method of claim 1, further comprising: receiving,at the computer, a request for the second workflow previouslytransmitted to the database; producing, at the computer, a query forretrieving the second workflow; and sending the query for the secondworkflow to the database in order to retrieve the second workflow. 8.The computer-implemented method of claim 1, further comprising:receiving, at the computer, a graph representation of the secondworkflow from the database; generating, at the computer, arepresentation of the second workflow based on the graph representation;and sending the representation to an interface associated with a secondcomputer, wherein the interface displays the representation of thesecond workflow.
 9. The computer-implemented method of claim 1, furthercomprising: receiving, at the computer, a request for first contentassociated with an operation included in the first workflow; producing,at the computer, a query for the first content; sending the query forthe first content to the database; receiving, at the computer, arepresentation of the first content from the database; producing, at thecomputer, a representation of the first content based on therepresentation of the first content received from the database; andsending the representation of the first content to an interfaceassociated with a second computer, wherein the interface displays therepresentation of the first content.
 10. One or more non-transitorycomputer-readable media including instructions that, when executed byone or more processors, cause the one or more processors to perform thesteps of: receiving a first workflow that includes a plurality of shapesand a plurality of connections, wherein a first shape included in theplurality of shapes comprises a first representation for a first step ofthe first workflow; generating a set of database queries that, whenexecuted, produce a second workflow corresponding to the first workflow,wherein the second workflow includes a plurality of nodes and aplurality of edges, wherein a first node included in the plurality ofnodes comprises a second representation for the first step of the firstworkflow that is different than the first representation; andtransmitting the set of database queries to a database for execution.11. The one or more non-transitory computer-readable media of claim 10,wherein the first workflow is received from a web-based interfaceassociated with a computer.
 12. The one or more non-transitorycomputer-readable media of claim 10, further comprising receiving onlinecontent associated with at least one operation of the first workflow.13. The one or more non-transitory computer-readable media of claim 12,wherein the online content comprises content retrieved from an onlineresource specified by a URL.
 14. The one or more non-transitorycomputer-readable media of claim 13, wherein the content is retrievedfrom the online resource through a service that extracts metadata fromthe online resource.
 15. The one or more non-transitorycomputer-readable media of claim 10, wherein: the plurality ofconnections in the first workflow indicate a sequential ordering of aplurality of operations included in the first workflow; and theplurality of edges in the second workflow indicate a sequential orderingof a plurality of operations included in the second workflow.
 16. Theone or more non-transitory computer-readable media of claim 10, furthercomprising: receiving a request for the second workflow previouslytransmitted to the database; producing a query for retrieving the secondworkflow; and sending the query for the second workflow to the databasein order to retrieve the second workflow.
 17. The one or morenon-transitory computer-readable media of claim 10, further comprising:receiving a graph representation of the second workflow from thedatabase; generating a representation of the second workflow based onthe graph representation; and sending the representation to an interfaceassociated with a second computer, wherein the interface displays therepresentation of the second workflow.
 18. The one or morenon-transitory computer-readable media of claim 10, further comprising:receiving a request for first content associated with an operationincluded in the first workflow; producing a query for the first content;sending the query for the first content to the database; receiving arepresentation of the first content from the database; producing arepresentation of the first content based on the representation of thefirst content received from the database; and sending the representationof the first content to an interface associated with a second computer,wherein the interface displays the representation of the first content.19. The one or more non-transitory computer-readable media of claim 10,wherein the first workflow comprises a workflow associated with a clientmachine, and the second workflow comprises a workflow associated withthe database.
 20. A system, comprising: one or more memories storinginstructions; and one or more processors that are coupled to the one ormore memories and, when executing the instructions, are configured to:receive a first workflow that includes a plurality of shapes and aplurality of connections, wherein each shape represents an operation inthe first workflow, and each connection represents a relationshipbetween two operations in the first workflow; generate a set of databasequeries that, when executed, produce a second workflow corresponding tothe first workflow, wherein the second workflow includes a plurality ofnodes and a plurality of edges, wherein each node represents anoperation in the first workflow, and wherein each edge represents arelationship between two operations in the first workflow; and transmitthe set of database queries to a database for execution.